View clinical trials related to Pulmonary Arterial Hypertension.
Filter by:Pulmonary arterial hypertension (PAH) is a progressive disease that results in severe activity limitation and death. There are few treatments for PAH and the available medications are expensive, difficult to administer and have significant toxicities. (-)-Epicatechin is a non-toxic compound that naturally occurs in foods such as tea, wine and chocolate. Clinical intervention studies using dark chocolate in normal volunteers and subjects at risk for or with established cardiovascular disease have demonstrated improvements in peripheral and coronary vascular endothelial function, blood pressure, lipids, glucose tolerance and inflammatory markers. Our study intends to examine the hemodynamics effects of purified (-)-epicatechin in subjects with pulmonary arterial hypertension. We hypothesize purified (-)-epicatechin will reduce pulmonary vascular resistance in patients with pulmonary arterial hypertension.
The purpose of this study is to compare the pharmacokinetics of two Traclear 62.5 mg tablets and one HGP1206 125 mg tablet in healthy male volunteers.
Pulmonary arterial hypertension (PAH) is a disease that causes raised blood pressure in blood vessels that pick up oxygen from the lungs. It has a life expectancy similar to some cancers. There is treatment available but there is no cure. We now know that PAH is associated with weakness in the muscles in the legs, which contributes to the symptoms patients' experience. Researchers believe that certain proteins found in high levels in the blood of patients with other chronic diseases can affect muscle function and growth. One of these proteins is called growth differentiating factor (GDF) 8, high levels of which are associated with muscle weakness in chronic obstructive pulmonary disease(COPD) and heart failure (HF). Interestingly there are drugs available which block the actions of GDF-8 on muscle cells which has been shown in animals to result in increased muscle size. A related protein called GDF-15 is found in elevated levels in patients PAH, and is linked to prognosis. Our preliminary data suggests that GDF-15 can also directly influence muscle size in a number of situations. We aim to investigate the role of GDF-15 and related molecules in the development of muscle weakness in patients with PAH. We will do this by measuring certain markers of muscle weakness and taking blood and muscle samples in patients and controls. We will then compare the levels of GDF-15 in these tissues in those with and without muscle wasting. We hope this work will lead to a greater understanding of the role of GDF-15 in the development of muscle weakness in patients with PAH. GDF-15 levels may be important in allowing us to define which patients have muscle weakness. In the future we aim to perform a clinical trial of drugs which block the actions of GDF-15.
On exposure to hypoxia (low oxygen) the normal response is for pulmonary arterial systolic blood pressure (PASP, blood pressure through the lungs) to increase. We have previously shown that raising iron by giving an infusion of iron into a vein reduces this pressure rise and that lowering iron by giving a drug that binds iron, magnifies this response. This is potentially a clinically important observation since iron-deficient people may be at increased risk of pulmonary hypertension if exposed transiently or permanently to hypoxia due to lung disease or residence at high altitude; furthermore if this were true then intravenous iron could be an important treatment in this patient group in the event of hypoxic exposure. The observed effects of iron on PASP are likely to be because iron levels affect oxygen sensing. Low iron levels make the body behave as if exposed to low oxygen by inhibiting the breakdown of the family of oxygen-sensing transcription factors, 'hypoxia inducible factor' or HIF. This includes one of the body's normal responses to low oxygen levels - raising blood pressure through the lungs. This study will answer the question (1) do iron-deficient volunteers have a greater rise in PASP with hypoxia than those who are iron-replete, and (2) does giving intravenous iron cause a greater reduction in the rise in PASP in those who are iron-deficient than iron-replete? The purpose of this study is not to test the safety or clinical efficacy of iron which is already known.
SYMPHONY Extension is an extension of AC-055-401, a multi-center, open-label, single-arm, Phase 3b study of macitentan in patients with Pulmonary Arterial Hypertension to psychometrically validate the PAH-SYMPACT instrument. The objective is to assess the long-term safety of macitentan in subjects with PAH beyond the treatment in the AC-055-401 study.
SYMPHONY is prospective, multi-center, open-label, single-arm, Phase 3b psychometric validation study of the PAH-SYMPACT, a new quality of life questionnaire for patients with pulmonary arterial hypertension. Patients will be in the study for 5 1/2 months, 4 months of which they will receive macitentan, 10 mg, once daily. The primary objectives are to demonstrate the final content validity of the PAH SYMPACT instrument, to demonstrate the psychometric characteristics of reliability and construct validity of the PAH-SYMPACT instrument, and to demonstrate the ability of the PAH SYMPACT instrument to detect change. The secondary objective is to assess the safety of macitentan in patients with pulmonary arterial hypertension. The exploratory objective is to explore the effects of macitentan on PAH symptoms and their impact (as measured by the PAH-SYMPACT) in patients with pulmonary arterial hypertension.
The purpose of this study is to determine whether pulmonary arterial hypertension can worsen or even cause sleep apnea. It is hypothesized that if pulmonary arterial hypertension does indeed worsen or cause sleep apnea, then the treatment should first focus on the underlying pulmonary arterial hypertension instead of the sleep apnea. To determine if a person has sleep apnea, they will undergo one overnight polysomnogram (sleep study). If it is found that they have mild to moderate sleep apnea, then the subject will be invited to continue in the study and their pulmonary arterial hypertension will be treated by their managing primary physician. After the subject has had treatment for their pulmonary arterial hypertension, the study center will have them return for a follow up sleep study to learn the effects of pulmonary arterial hypertension treatment management on their sleep apnea, 12-24 weeks after the first sleep study.
The aim of the study is to determine relevant hemodynamic parameters for the diagnostics of pulmonary arterial hypertension (PAH) by dynamic contrast enhanced dual-energy CT (DE-CT). In this prospective study the investigators validate DE-CT results of patients against hemodynamic parameters from right heart catheterisation and control the results by other clinical investigations. The investigators expect that using this non-invasive method, parameters relevant for the diagnosis of the patients with PAH, like pulmonary blood volume, blood flow and perfusion heterogeneity, can be determined.
SUMMARY Rationale: Pulmonary arterial hypertension (PAH) can be a rapidly progressive disorder and is associated with a high mortality rate, despite medical intervention. With the availability of effective therapy, early disease detection is an important strategic objective to improve treatment outcomes. Resting echocardiography is currently the recommended screening modality for high-risk population groups. However, it is clear that abnormalities in resting hemodynamics (and symptoms) are late sequelae of the pathobiological processes that begin in the distal pulmonary arteries. Exercise stress may unmask early pulmonary vascular dysfunction, however the definition, clinical significance, and natural history of 'exercise PAH' remain undefined. However, based on clinical experience and literature the prevalence is estimated at ~ 20%.Treatment with endothelin receptor blockers has shown a beneficial influence on the clinical performance in patients with exercise induced PAH due to systemic sclerosis and primary pulmonary hypertension. Whether endothelin receptor blockers decrease pulmonary pressures and improve clinical outcome in patients with exercise induced pulmonary arterial hypertension due to congenital heart disease is unknown. Objective: Identify congenital heart disease patients with exercise-induced pulmonary arterial hypertension. Analyze changes in pulmonary arterial pressures at peak exercise in patients with exercise induced pulmonary arterial hypertension before and after treatment with bosentan, compared to placebo. Study design: Randomized placebo controlled trial with a study period of 26 weeks. Study population: Adult congenital heart disease patients with exercise induced pulmonary arterial hypertension (n=40) from the Academic Medical Centre, Amsterdam. Intervention: After randomization one group (n=20) receives a 125 mg tablet of Bosentan twice daily for 6 months. The other group (n=20) receives placebo for 6 months. Main study parameters/endpoints: To determine wether bosentan (endothelin receptor inhibitor) decreases mean pulmonary arterial pressure at peak exercise in adult congenital heart disease patients with exercise induced pulmonary arterial hypertension. Furthermore the change in cardiopulmonary exercise capacity and right ventricular function will be investigated. Nature and extent of the burden and risks associated with participation, benefit and group relatedness: All investigations, blood analysis excepted, are non-invasive and free of risk. The burden for the patients mainly consists of the time that is consumed by the investigations, namely: history taking + physical examination (15 min); Quality-of-Life- score (15 min); laboratory tests (electrolytes, creatinine, urea, albumin and neurohormones, troponin T); 12 lead electrocardiogram (10 min); exercise echocardiography (30 min); cardiovascular exercise testing (30 min). The trial medication has a potential risk of liver damage, which will be monitored regularly by laboratory testing of liver transaminases.
The main purpose of this study is to evaluate the safety and efficacy of tadalafil in pediatric participants with pulmonary arterial hypertension. Participants will receive study treatment for 6 months in the double-blind period (Period 1), and then will be eligible to enroll into an open-label 2 year extension period (Period 2) during which participants will receive tadalafil.